Ultrastructure and molecular characterization of a microsporidium, Tubulinosema hippodamiae, from the convergent lady beetle, Hippodamia convergens Guérin-Méneville

Effects of the microsporidian pathogen, Nosema adaliae (Nosematidae) on the seven-spotted lady beetle, Coccinella septempunctata L. (Coleoptera: Coccinellidae)

Lady beetles are important predators in nature. Some species, including the two-spotted lady beetle, Adalia bipunctata L., are native to North America, whereas others, such as the seven-spotted lady beetle, Coccinella septempunctata L., have been introduced in North America for pest control on agriculture crops. Microsporidia are obligate pathogens that cause chronic disease, and these pathogens are known to infect several lady beetle species. Lady beetles are cannibalistic and, because many species share a given landscape, there is potential for microsporidia to infect susceptible coccinellids when infected eggs are eaten. The objective of this study was to examine the effects of the microsporidium Nosema adaliae isolated from A. bipunctata on C. septempunctata fitness (larval development and mortality, sex ratio, adult longevity and fecundity). Mortality was higher for C. septempunctata larvae that ate four A. bipunctata eggs (≥96% mortality) than for those that ate only one (<63.8%), suggesting that the mortality observed was influenced by the number of eggs eaten. A. bipunctata eggs contain adaline and adalinine, two species-specific alkaloids that have been shown to be detrimental to C. septempunctata larvae. Development of larvae that consumed one uninfected or one N. adaliae-infected A. bipunctata egg, did not differ significantly (20.5 ± 0.2 d and 21.3 ± 0.4 d, respectively) and, although mortality remained high for these larvae (53.5% and 65.6% mortality, respectively), these values also did not differ significantly (p = 0.05). Over a 60-d period, mean fecundity for C. septempunctata adults that ate one uninfected A. bipunctata egg as first-instar larvae was significantly greater (776.6 ± 122.0 eggs) than those that ate one N. adaliae-infected egg (335.6 ± 86.6 eggs, p = 0.005). Larvae from the former group also lived significantly longer (58.2 ± 1.8 d) than did those from the latter group (38.4 ± 6.4 d, p = 0.010). Sex ratios of adult beetles did not differ significantly. Because A. bipunctata and C. septempunctata share similar habitats, it is reasonable to expect these two coccinellids to encounter one another in nature. Results of this study show that the consumption of only one infected A. bipunctata egg by C. septempunctata larvae can result in high larval mortality and reduced fecundity.

Effects of microsporidiosis and food availability on the two-spotted lady beetle, Adalia bipunctata L., and convergent lady beetle, Hippodamia convergens Guérin-Méneville

Two species of microsporidia have been described from lady beetles that are commercially available for biological control: Nosema adaliae from the two-spotted lady beetle, Adalia bipunctata L., and Tubulinosema hippodamiae from the convergent lady beetle, Hippodamia convergens Guérin-Méneville. These pathogens delay larval development under controlled conditions, but little is known regarding the effects that microsporidia cause when their hosts are subjected to stressful conditions that are often experienced in nature. In this study, the combined effects of microsporidiosis (N. adaliae on A. bipunctata and T. hippodamiae on H. convergens) and irregular food availability were observed on host fitness (larval development and mortality, sex ratios, and adult morphometrics). For each beetle species, 24 h-old larvae were provided either an uninfected or microsporidia-infected conspecific egg. After the egg was eaten, some larvae were provided an abundance of aphids daily, whereas others were provided aphids on an irregular basis. Development was delayed significantly for larvae that consumed a microsporidia-infected egg, and for those fed irregularly. For A. bipunctata, a significant interaction was observed between infection status and food availability. This suggests that N. adaliae-infected A. bipunctata larvae that have an irregular supply of aphids undergo further developmental delays than those with a generous food supply. This interaction was not observed for T. hippodamiae-infected H. convergens. For both species, larval mortality and sex ratios did not differ significantly, regardless of infection status or food availability. Adults that were fed daily as larvae were significantly larger than those fed irregularly. However, the elytra of N. adaliae-infected A. bipunctata were significantly larger than the elytra of their uninfected cohorts, and T. hippodamiae-infected H. convergens had wider pronota and head capsules than uninfected H. convergens. Because N. adaliae and T. hippodamiae prolong larval development of their respective hosts under controlled conditions, one would expect these pathogens to cause more profound effects when their hosts experience stressful conditions. The results from this study indicate that this was the case for A. bipunctata, but not for H. convergens.

The influence of microsporidian pathogens from commercially available lady beetles on larval development of the green lacewing, Chrysoperla carnea, in the absence of infection

In North America, more than 70 species of natural enemies are available for pest control, including the aphid predators, Adalia bipunctata L. (two-spotted lady beetle) and Hippodamia convergens Guérin-Méneville (convergent lady beetle), and the generalist predator Chrysoperla carnea Stephens (green lacewing). The two lady beetle species are known to host microsporidian pathogens: Nosema adaliae was originally described from Adalia bipunctata and Tubulinosema hippodamiae from H. convergens. Microsporidia are spore-forming pathogens that typically produce chronic, debilitating disease. Because the spores of both pathogens are transovarially transmitted through beetle eggs, the predation behavior of lacewing larvae provides an opportunity for the transmission of these pathogens when infected lady beetles and lacewings share the same local environment. In this study, uninfected and microsporidia-infected eggs from A. bipunctata and H. convergens were offered to C. carnea larvae. The development of larvae that consumed N. adaliae-infected eggs was not affected, but larval development was prolonged by almost 3 days for those that consumed two or more T. hippodamiae-infected eggs. Prolonged larval development is considered to be costly because larvae remain vulnerable to cannibalization by sibling larvae or other predators. Longevity did not differ significantly between sexes of C. carnea, and the sex ratio of newly eclosed adults did not differ from the previously reported sex ratio of 1♂: 1♀. Upon examination by light microscopy at the end of the trial, two C. carnea larvae were infected with N. adaliae and none were infected with T. hippodamiae, suggesting that T. hippodamiae influenced lacewing larval development without establishing an infection.

Evolutionary ecology of microsporidia associated with the invasive ladybird Harmonia axyridis

Invasive species are characterized by the rapid growth and spread of their populations after establishing a foothold in new habitats, and there are now many examples of such species negatively affecting biodiversity and the economy. It is unclear why some species can become successful invaders, whereas most (even if closely related) remain noninvasive. We previously proposed a hypothesis that parasites associated with invading species can promote their invasive success if they are harmless toward the invaders but harmful to their competitors and/or predators in the newly colonized habitat. Here we discuss whether microsporidia that have recently been discovered in the invasive ladybird Harmonia axyridis contribute to its invasive success. We show that all H. axyridis beetles sourced from diverse collection sites all over the world carry abundant microsporidia. This suggests that both native and invasive H. axyridis populations are associated with these tolerated parasites, which were likely to have existed in native populations before expansion rather than being acquired in newly colonized areas. We describe the pathogenesis of the microsporidia during different developmental stages of H. axyridis and we address the possibility that the predation of its infected eggs and larvae by competing native ladybird species may lead to their infection and ultimately to their decline. Finally, we discuss our initial hypothesis: microsporidia that are tolerated by an invasive vector insect can be active against susceptible native competitors and/or predator species.

Nosema adaliae sp. nov., a new microsporidian pathogen from the two-spotted lady beetle, Adalia bipunctata L. (Coleoptera: Coccinellidae) and its relationship to microsporidia that infect other coccinellids

The two-spotted lady beetle, Adalia bipunctata L., is a tree-dwelling lady beetle endemic to parts of Europe, Central Asia and North America that is commercially available for aphid control in Europe and North America. Lady beetles host a wide variety of symbionts including parasitoids, viruses, eugregarines, fungi, bacteria, nematodes and microsporidia. Four species of microsporidia have been described from lady beetles, and an undescribed microsporidium was recently isolated from local populations of A. bipunctata in Nova Scotia, Canada. In a previous study, this pathogen prolonged the development of A. bipunctata larvae but had no effect on adult fecundity, longevity or sex ratios. The objective of this study was to formally describe the microsporidium by means of its ultrastructure, tissue pathology and molecular characterization. All stages of the microsporidium were diplokaryotic and developed in direct contact with the host cell cytoplasm. Mature spores measured 4.25±0.09×1.82±0.03μm (SE, n=49, from micrographs) and fresh spores measured 6.10±0.06×3.01±0.05μm (±SE, n=60; range: 5.0-6.9×2.18-3.86μm). The polar filament was isofilar with 10-18 coils that were frequently arranged in a single row. The lamellar polaroplast was not typically visible and spores contained a relatively small posterior vacuole. Both the flight muscles and fat body were heavily infected and a large number of spores were observed within and between the cells of these tissues. The ovaries, developing oocytes, spermatocytes and accessory glands within the testes, midgut epithelium, Malpighian tubules, ileum, colon, and ventral nerve cord were also infected but not as heavily. Connective tissue near the cuticle and surrounding the trachea were lightly infected. The presence of spores in both the alimentary canal and ovaries (particularly within developing oocytes) suggests that the microsporidium can be transmitted per os (horizontally) and transovarially (vertically). Molecular analysis of the genome of the microsporidium described in this study was 97% similar to Nosema bombi and 96% similar to Nosema thomsoni, Nosema vespula and Nosema oulemae. Based on information gained during this study, we propose that the microsporidium in A. bipunctata be given the name Nosema adaliae sp. nov.

The convergent lady beetle, Hippodamia convergens Guérin-Méneville and its endoparasitoid Dinocampus coccinellae (Schrank): the effect of a microsporidium on parasitoid development and host preference

Convergent lady beetles, Hippodamia convergens Guérin-Méneville are host to the braconid endoparasitoid, Dinocampus coccinellae (Schrank) and the microsporidian pathogen, Tubulinosema hippodamiae. The interrelationship between the endoparasitoid and the pathogen in H. convergens adults under laboratory conditions was examined by quantifying the effect of microsporidiosis on D. coccinellae development and host preference. Uninfected wasps were provided either uninfected or T. hippodamiae-infected beetles as hosts and the development of their progeny was observed over 30 days. The duration of endoparasitoid development from egg deposition in the host until adult eclosion for D. coccinellae did not differ significantly, regardless of the infection status of the host beetle. All wasp progeny that developed within, and emerged from, T. hippodamiae-infected beetles were infected with the microsporidian pathogen (n = 48; 100% transmission). Infected D. coccinellae adults were also provided either uninfected or T. hippodamiae infected host beetles so that the development of their progeny could be assessed over 30 days. Endoparasitoid development did not differ significantly; however, a significantly greater proportion of beetles stung by microsporidia-infected wasps did not contain an endoparasitoid larva when dissected at the end of the 30-day trial when compared to those stung by uninfected wasps. This suggests that the pathogen may reduce wasp fecundity or egg viability. Examination of paraffin-embedded D. coccinellae adult tissues revealed an extensive microsporidian infection throughout all major organs and tissues with exception of the ovary. During host choice trials, uninfected and microsporidia-infected D. coccinellae adults pursued, took an ovipositional stance, and attacked uninfected beetles more often than microsporidia-infected hosts but these observations did not differ significantly (P > 0.05).